JPH09221721A - Sound insulating device for road side and tunnel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To weaken sounds by combining resonators corresponding to various frequency ranges with one another. SOLUTION: Resonators 10 are provided in a parallelepiped component 1 and a resonator unit 9 surrounded by a casing 2 is provided. In this case, the whole or some of the resonators 10 are set in the frequency range of 200-30000Hz. And in order to form a cavity resonator, a resonator body 11 is provided so as to be combined with an integral type body. The body 11 has a perforated front wall 12 and a partition wall 13 is projected from the wall 12. And to damp sounds between a sound function front wall 3 of the casing 2 and the body 11 and between a rear wall 6 and the body 11, a mineral fiber mat 14 is provided. The thickness of the mat 14 is determined so as to have fluid resistance of 40-80mPas/m<2> , particularly 50-70mPas/m<2> . As a result, bandwidth for frequency range can be adjusted corresponding to a sound source.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soundproofing device composed of flat components having a plurality of resonators and which can be combined to form a noise absorption system, for example roadside and tunnel soundproofing devices. It is about.

[0002]

BACKGROUND OF THE INVENTION Soundproofing devices, especially noise barriers, absorb at least part of the impact sound and diffusely reflect part of it.
Such sound barriers can have a structure made of concrete, wood or metal, and can be planted. In addition, sound absorbing fillers made from fibrous materials such as mineral wool are also known. A noise barrier comprising a resonator and acting as a cavity resonator is more effective at damping sound. Such noise barriers are known, for example, from the patent DE-A-23 14 396 as well as the specification of CH 578 657. The resonator-based sound insulation device described in the two documents mentioned above has excellent sound absorption properties.
However, the possibility of extending the sound absorption into the rather wide frequency range mentioned in said document is either very complicated and expensive or unsatisfactory.

[0003]

SUMMARY OF THE INVENTION It is therefore an object of the invention to provide a known sound-proof device operating on a resonator, so that the device can be effectively matched to disturbing noise sources with a minimum of effort and expense. To improve.

[0004]

According to the present invention, there are provided:
The gist of the soundproofing device according to any one of 5 is.

[0005]

The soundproofing device of the present invention has mutually different resonators for different frequency ranges. In the present invention, the individual resonators are acoustically isolated from each other, so that there is no interconnection of the plurality of resonators. Instead,
The individual resonators have different spatial structures. In particular, the depth of the resonator chamber and the design of the holes in the resonator are configured differently for the different resonance functions desired. Thus, for a simple noise barrier configuration,
It is possible to adapt to the frequency bandwidth of the noise source.
Since vehicles have different engines, engine speeds, and speeds, engine and tire noise can be emitted over a relatively wide frequency range, but efficiently to protect nearby residents, for example. This is especially important for road noise barriers that must be absorbed. The soundproofing device according to the present invention is suitable not only for dampening noise in other noise generating places such as an aircraft or a fire area, but also in roads. Known types of cavity resonators have a relatively narrow absorption range if they have the same structure. Therefore, a resonator with an absorption maximum of 800 Hz is still 700-900 Hz.
Can absorb frequencies in the range. According to the preferred embodiment of the present invention, various resonators having absorption maximums varying from 100 to 200 Hz at maximum are provided, but the difference is preferably smaller as the frequency is lower. By properly combining such different resonators and the corresponding amount distribution of the resonators, it is possible to adapt the absorbing action of the soundproofing device to the disturbing noise source both in terms of frequency bandwidth and predetermined frequency strength. is there. Therefore, the soundproofing device according to the present invention is about 2
It is possible to effectively reduce the sound over a wide range of 0 to about 3000 Hz. Small range within the above large range,
For example, 200 to 600 Hz or 400 to 1000 H
z, 1000-2000 Hz, and 1000-30
It is also possible to tune the resonator to accommodate the 00 Hz range.

The soundproofing device according to the invention has various possibilities of implementing various resonators. In one embodiment, the resonators are constructed identically in one component with several resonators, and in the soundproofing device there are different components that respond to different frequencies. For example, to form a noise barrier, the desired absorption frequency range can be obtained by the proper combination of such various components. However, it is also possible for at least one of the components to have different resonators for different frequencies.
The various resonators are preferably tuned to respond to neighboring frequency ranges. Such components with different resonators can also be combined with components with different or identical resonators only. Particularly expediently, regardless of the various properties of the resonator, the components are made exactly the same in terms of their appearance as well as their external dimensions. Therefore,
They can be combined randomly without causing any problems.

In one embodiment of the invention, in each case:
Each component comprises a plurality of resonators and preferably comprises at least two resonator units which are housed in a casing. The casing is made of, for example, a metal such as powder-molded coated aluminum, or wood, or other non-metallic material to absorb mechanical forces acting on the component. The front wall of the casing provided on the acoustic side of the resonator is perforated by known methods. The ratio of pores is preferably 50% or more of the front wall surface, and more preferably 60 to 90%. The air resistance of the perforated front wall should be as low as possible. This can be achieved by making the pore size of the front wall as large as possible, preferably 10 mm or more, more particularly 12 mm or more. However, the holes may be non-circular. Therefore, the front wall can also be made of slotted or diamond-shaped holes and expanded metal with a very high porosity. Self-excited vibrations of the front wall should be avoided, but can be prevented by corresponding profiling or rib formation.

Resonator units, which may have from about 20 to more than 100 resonators, can be formed from closed-cell plastics, in particular polystyrene, by known methods, thus providing a lightweight but reasonably stiff body. Can be formed.
The resonator cavity of an individual resonator can be formed by the perforated front wall of the resonator unit and the web-shaped partition and side wall laterally surrounding the resonator cavity. The inner wall of the resonator cavity is preferably smooth and flat. The back wall of the body of the resonator can be opened in a known manner, and the back wall of the resonator can be formed by the back wall of the casing. A fiber mat can be inserted between the rear wall of the casing and the resonator body as is known in the prior art. The fiber mat is hermetically supported on a partition or web of the resonator body so that the individual resonators are acoustically isolated from each other.

In one embodiment of the invention, at least a side-by-side resonator unit with mutually different resonators for different frequencies is provided in the individual components. The resonators in one resonator unit can be the same in each case, but in one component:
Different resonator units are arranged according to various frequencies. However, the resonator of the resonator unit is
They may be different from each other. The component is
It is possible to have the same or different types of resonator units. The resonator components can also have resonators with different spatial depths or horizontal lengths. This means that a resonator unit may be provided in which the resonators in that resonator unit have the same spatial depth but a different spatial depth than the resonators of another resonator unit. Further, it is possible to provide various resonators having different spatial depths in one resonator unit. The various space depths of the resonator are determined by the front wall of the resonator unit, more specifically, the foamed resonator body, because the front wall recedes at each location of the resonator having the smaller space depth. However, the spatial depth of the resonator can and preferably also be different at the rear, as a result of which the gap between the different resonator bodies and the casing back wall is It is also possible to make the correction by means of one or more corresponding correction parts forming the wall.

In the case of one component between the perforated front wall of the casing and the perforated front wall of the resonator unit, it is preferable to place a fiber mat or fiber plate. The fluid resistance of this fiber mat with respect to air is important for the sound absorption properties of the soundproofing device according to the invention. (DIN52213
40-80 K Pas / m ² ,
In particular, a fluid resistance in the range of 50 to 70 K Pas / m ² is particularly suitable.

Apart from the air-permeable front wall, the casing of the component is preferably substantially closed, but it is convenient to have small discharge openings for permeate and / or condensed water. Such a discharge opening is preferably airtight with respect to the perforated front wall and is preferably provided at a location where water can flow out. It is also convenient to provide a heat and moisture suppression layer near the rear wall of the casing, especially if the latter is made of metal.
Such layers prevent condensation on the inside of the casing back wall and prevent rust. This is, as recommended, where it is possible for air to enter and leave the resonator chamber freely from the outside because the resonator chamber is not separated from the outside by a barrier layer, such as a thin film or foil. It is particularly convenient.

Other features of the invention can be determined from the following description of an exemplary embodiment with reference to the drawing and the dependent claims. Individual features may be implemented alone or in combination in those examples.

[0013]

1 is a cross-sectional view of a soundproofing device according to the present invention, and FIG. 2 is a vertical cross-sectional view of components of another embodiment.

In the embodiment described in connection with FIGS. 1 and 2, a soundproofing device is provided which is formed from a plurality, typically 50 or more, of flat parallelepiped components 1 or, for example, Staggered, i.e. parallel and alternating, to form walls. Other configurations are possible.
The component 1 has a casing 2 made, for example, of powder-molded coated sheet aluminum. The casing 2 has holes 4, the proportion of the holes 4 being at least about 50%, preferably 70-80% of the sound-acting front wall 3. In the casing 2, the narrow side 5 and the rear wall 6 are closed except for a small drain hole 7 for dew condensation water on the lower side 8 near the rear wall 6.

If the components are staggered, in each case the two components can be combined back to back to form a composite component,
Instead of a back wall, the casing has a partition or intermediate wall for acoustically isolating the resonator.

In the above embodiment, each component 1
Has a height of 50 cm, a length of 4 mm, and a depth of about 13 cm. Each component has a height of about 48 cm and a length of about 9
There are 4 resonator units of 8 cm and depth of about 9 cm,
They are arranged vertically in a straight line in the component 1. The resonator unit 9 includes a plurality of, for example, 50, cavity resonators 10 that determine a frequency range to be absorbed. A resonator body 11 is provided which assembles the resonator 10 into a substantially integral body to form a cavity resonator. The resonator body has a general perforated front wall 12 from which a partition 13 is defined which mutually defines the individual resonators. The partition walls 13 can be configured to intersect by organizing the resonators 10 so that the plan view is rectangular or square. However, the plan view of the resonator may be diamond-shaped or honeycomb-shaped. For example, a resonator that absorbs 800 ± 100 Hz
There can be 81 (9 × 9) holes in an area of 8.5 × 8.5 cm. The diameter of the hole is about 4 mm and the front wall 12
The hole depth at is about 17 mm. The hole ratio in the front wall is about 17% and the resonator depth is about 8 cm.
Dimensions for other frequency ranges can be determined by the Helmholtz equation.

In the embodiment described above, the resonator body 11 is open at the rear and the acoustic back of the resonator can be constructed in various ways as will be described.

Due to the additional acoustic damping between the front wall 3 of the casing and the resonator body 11 and between the rear wall 6 of the casing and the resonator body 11, mineral fiber mats 14 and 1 are provided.
5 or 15 'is provided and the resonator body 11 is fixed between the mineral fiber mats. The thickness of the mineral fiber mat 14 on the perforated front side is about 20 mm and the flow range is (50 to 7 measured according to DIN 52213,
0 KNS / m ² or 50 to 70 K Pas / m ²
50-70 Rayl. This fluid resistance has proven to be particularly favorable for the sound absorption properties of the soundproofing device according to the invention. Volume density is about 180 kg / m
³ The rear mineral fiber mat 15 or 15 ′ is slightly softer and looser than the front mineral fiber mat 14. The rear mineral fiber mat has a function of absorbing sound near the rear wall of the resonator and scattering of the reflection portion. Its bulk density is usually about 60 kg / m ³ and its material thickness is at least 10 mm. For larger materials, thickness compression can occur.

The soundproofing device according to the invention is of various types,
It has a cavity resonator operating in various frequency ranges. The components of the soundproofing device can have the same resonator in each case. The resonators are different for each component, ie there are at least two, preferably at least four different component types. It is also advantageous that the component can have different resonators in each case, for this purpose several resonator units can be provided, in each case the same resonator but with different resonator units. Is. It is also possible to combine this structure with the structure described above.

The individual resonators can also have different structures within the resonator unit. Furthermore, resonator units with such different resonators may be
Alternatively, it can be combined with a resonator unit or component of the type described above. In this way, it is possible in a simple way to adapt the soundproofing device to specific requirements. Whether the resonator unit or resonator contained in the component is different or the same, the component has exactly the same appearance,
It is possible to construct an integrated soundproofing device with components operating in different frequency ranges.

The embodiments of the present invention shown in FIGS. 1 and 2 belong to a type in which the structure of the resonator unit is different in each case, that is, a type in which the resonator absorbs different frequency ranges. Is. In the embodiment shown in FIG. 1, the partition wall 13 of the resonator body has different depths as a function of the spatial depth of the resonator. Depending on the conditions of the Helmholtz equation, it is also possible to change the diameter of the hole 16 of the perforated front wall 12 and the depth of the hole, that is, the wall thickness of the front wall 12 in order to match the desired frequency range. In order to compensate for resonator cavities of different depths, the resonator device is equipped with a rear wall 1
7, the rear wall 17 is in close contact with the open side of the resonator body 11, the rear wall 17 is thicker at the portion where the partition wall 13 is shorter, and at the portion where the partition wall is longer. Is depressed accordingly. In this embodiment, the mineral fiber mat 15 is provided between the correction rear wall 17 and the resonator body 11. If desired, the mineral fiber mat 15 can be subdivided into several pieces.

In the embodiment according to FIG. 2, the rear of the resonator is formed by the rear wall 6 of the casing 2. The partition wall 13 ′ of the resonator body 11 ends in one plane. Correspondingly, the mineral fiber mat 15 'is also flat. When manufacturing resonators having different depths, since the perforated front wall 12 'has a staircase structure, front wall portions provided with steps are provided. Again, the depth and diameter of hole 16 'is
Appropriate changes can be made to obtain the desired resonance condition. The front wall 3 of the casing 2 is substantially flat, apart from profiling for stiffening the front wall,
The cavity formed by the stepped structure of the front wall 12 ′ of the resonator body 11 is suitably filled with an additional mineral fiber matting part 18, which further reduces the sound. Inside the rear wall 6 of the casing, a resonator cavity is insulated from the rear wall 6 of the casing in a heat-insulating and moisture-isolated manner to prevent condensation on the rear wall of the casing, for example by means of tarboard or closed-cell foam. Layer 19 is conveniently provided. This is advantageous in the case of the present invention, where free air access to the cavity of the resonator 10 is possible via the casing front wall 3, the mineral fiber mat 14, the holes 16 or 16 '. The free air approach allows moisture to enter the resonator as a function of weather, thereby
When water gets cold, it may adhere to the rear wall, so
It is particularly suitable.

[Brief description of drawings]

1 is a cross-sectional view of a soundproofing device according to one embodiment of the present invention.

2 is a vertical cross-sectional view of a component according to another embodiment of the present invention. FIG.

[Explanation of symbols]

 1 parallelepiped component 2 casing 3 sound effect front wall 4 hole 5 narrow side 6 rear wall 7 drainage hole 8 lower side 9 resonator unit 10 resonator 11 resonator body 12 perforated front wall 13 partition wall 14 mineral fiber mat 15 mineral fiber Matt 16 Hole 17 Rear wall 18 Mineral fiber mat

Claims (15)

[Claims] 1. A soundproofing device, such as for roadside and tunnel use, which comprises a plurality of resonators (10) and is formed from flat components (1) which can be combined with each other to provide a sound damping device. A soundproofing device comprising various resonators (10) according to various frequency ranges. 2. The resonator (10) has a frequency range 200-
The soundproofing device according to claim 1, wherein the soundproofing device is set to 3000 Hz or a part thereof. 3. A resonator (1) in the component (1).
0) is the same in each case and different components (1) according to different frequencies are provided in the soundproofing device, the soundproofing device according to claim 1 or 2. 4. At least individual components (1)
The soundproofing device according to claim 1 or 2, characterized in that it has different resonators (10) according to different frequencies. 5. The soundproofing device component (1) is characterized in that, apart from its various features, it has the same external dimensions in each case, and moreover has the same appearance. The soundproofing device according to any one of claims 1 to 4. 6. Individual component (1) of each case
Comprises a plurality of resonators (10) and a casing (2)
A soundproofing device according to any one of the preceding claims, characterized in that it comprises at least two resonator units (9) surrounded by. 7. A resonator unit is provided in at least the individual components, which resonator unit in turn has different resonators (10) according to different frequencies. The soundproofing device according to any one of claims 1 to 6. 8. The resonator of the resonator unit is the same in each case, and various resonator units corresponding to various frequencies are arranged in the component. 7. The soundproof device according to any one of 7. 9. A resonator (10) of a resonator unit (9).
Are different from each other, and within the component (1) the same and / or different types of resonator units (9)
The soundproofing device according to claim 1, wherein the soundproofing device is included. 10. The soundproofing device according to claim 6, characterized in that the resonator unit (9) comprises resonators (10) with different spatial depths. 11. The resonator unit (9) has a unitary body (11) which lies in one plane on a typical perforated front wall (12) of the resonator (10). ), Preferably at the open rear of the integral body (11) there is a corrector for different resonator depths. . 12. A resonator back wall is formed between the integral body (11) and the casing back wall (6) and preferably has different thicknesses as a function of different resonator depths.
Soundproofing device according to any one of the preceding claims, characterized in that there is at least one correction member (17). 13. The fiber mat (14) between the resonator unit (9) and the air permeable front wall (3) comprises 40 to 8 fibers.
0 mPas / m ² , especially 50 to 70 mPas / m
A fluid resistance of ^{2 is provided, and} the fluid resistance is 6 to 1.
The soundproof device according to any one of 2. 14. Aside from the air-permeable front wall (3), the casing (2) is substantially sealed, on its lower side (8) for permeated and / or condensed water. 1 to 1, characterized in that there is a discharge opening (7).
The soundproofing device according to any one of 3 above. 15. The soundproofing device according to claim 6, wherein a heat and moisture absorbing layer 19 is provided in the vicinity of the inside of the rear wall of the casing, particularly in the case of a metal casing.